The present work discusses an upwind case study about full scale measurements gathered during navigation on the Politecnico di Milano Sailing Yacht Laboratory (SYL). SYL is a 10m sailing boat, consisting in standard instrumentation, integrated dynamometer, a 3D flying shape detection system and distributed pressure sensors on sails. Particular attention was devoted to pressure measurements: full scale results are analysed and compared with wind tunnel test. The comparison of full scale/wind tunnel pressure distributions holds consistently, with the highest differences observed in the regions close to the leading edge. Critical aspects related to performing full scale measurements are also discussed.

It’s well known that large differences commonly exist between a computer based original design shape and the resulting flying shapes of offwind sails. Fluid-structure interaction codes based on CFD and FE techniques are nowadays under development and they represent appealing tools useful to close this gap: in fact potential improvements to the offwind sail design process could be provided by developing an offwind sail design database (a collection of baseline designs appropriate for different applications) based upon representative flying shapes rather than present style based upon design shapes. Up to date numerical codes still need a massive validation work and both wind tunnel tests as well as on water testing at full scale can give a substantial contribution, supposing that reliable flying shapes are provided reflective of the realistic sailing and trim conditions. This paper presents a new tool based on noncontact methods which allows for measuring sail flying shapes in the wind tunnel environment as well as at full scale in real life conditions. The proposed method has been validated during a wind tunnel campaign on both symmetric and asymmetric spinnakers carried out at Politecnico di Milano during an Offshore Racing Congress project aimed at revising offwind sails aerodynamic coefficients and ORC VPP aerodynamic model. Some results are shown comparing design shapes versus flying shapes and potential improvements to the offwind sail design process by developing an offwind reference sail design database are discussed.